JPH09217851A - Air valve device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To relax the occurrence of water hammer phenomenon to a long tube water passage. SOLUTION: An air valve 20 is arranged in a feed water pipe 14 through a water holding pipe 18. A fluid passage 30 in which inflow resistance of water from the water holding pipe 18 to the feed water pipe 14 is high and discharge resistance is low is located in the water holding pipe 18. The fluid passage 30 comprises a valve element 32 closed by inflow of water through the water holding pipe 18 to the fed water pipe 14 and opened through a reverse flow; and a small hole 34 formed in the valve element 32.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air valve device for alleviating a water hammer phenomenon which may occur when a pump for supplying water to a water pipe forming a long pipe water channel suddenly stops. is there.

[0002]

2. Description of the Related Art As shown in FIG. 3, a water supply pipe 14 forming a long water passage is provided from a suction water tank 10 toward a discharge water tank 12 having an actual head. In a pumping pump system or the like that is supplied with water, an air valve 20 is generally provided on the convex portion 14a of the water supply pipe 14 so that the air in the water supply pipe 14 is reliably exhausted.

[0003]

In the system shown in FIG. 3, when the pump 16 is suddenly stopped due to the interruption of the power source or the like, the flow rate in the water supply pipe 14 is suddenly changed, and the water supply pipe 14 is suddenly changed. The pressure inside changes rapidly. That is, even if the operation of the pump 16 is stopped, the water in the water supply pipe 14 is discharged due to inertia and tries to move to the water tank 14 side. Therefore, the inside of the water supply pipe 14 has a negative pressure, and the air flows into the water supply pipe 14 via the air valve 20. And after a while, the water pipe 1
The movement due to the inertia of the water in 4 is stopped, and the inside of the water supply pipe 14 is moved toward the suction water tank 10 in reverse. Therefore, the air in the water supply pipe 14 is exhausted through the air valve 20, and the air valve 20 is closed when the exhaust of the air is completed. When the air valve 20 is closed, the movement of water in the water pipe 14 is suddenly stopped, so that the pressure in the water pipe 14 is rapidly increased. This is the so-called water hammer phenomenon, and the water pipe 1
4 and the air valve 20 are easily damaged. In this phenomenon, as the movement amount (distance) of the water in the water pipe 14 due to the inertia is larger, the flow velocity of the water immediately before the air valve 20 is closed is increased due to the backflow, and as a result, the air valve 20 is closed. At this time, the change in the flow velocity of water becomes large and the pressure rise also becomes large.

As a countermeasure against the water hammer phenomenon, there is a method in which a large-capacity flywheel is attached to the pump 16 so that the pump 16 does not suddenly stop even when the power is cut off. In addition, by connecting a large capacity pressure tank or surge tank to the water supply pipe 14,
Even if the water in 4 moves due to inertia, the pressure in the water supply pipe 14 may be maintained at a positive pressure.

However, the installation of the flywheel, the pressure tank, or the surge tank requires a large installation space, and there is a problem that the installation is limited depending on the conditions of the installation site.

As another technique for alleviating the water hammer phenomenon, there are those proposed in Japanese Utility Model Publication No. 60-534 and Japanese Utility Model Publication No. 61-37912. All of these technologies are designed to reduce the flow velocity of water immediately before the air valve is closed, and to slowly stop the sudden stop of water movement due to the closing of the air valve. Is.

In the air valve for reducing the flow velocity of the water, when the water in the water pipe 14 moves due to inertia, the air flows into the water pipe 14 so that the air flows into the water pipe 14. May remain. If air remains in the water supply pipe 14, there is a risk of causing an air hammer phenomenon when the pump 16 is restarted. Therefore, there is a problem in that restarting the pump 16 requires a careful air vent operation so as not to cause an air hammer phenomenon, and the operation is complicated.

The present invention provides an air valve device which suppresses the water hammer phenomenon by a completely different action from the above-mentioned proposed technique.

[0009]

In order to achieve the above object, an air valve device of the present invention is provided with an air valve in a water supply pipe forming a long water passage through a water retention pipe, and the water supply pipe and the water retention pipe are provided. In between or in the water retaining pipe, a fluid passage having a large resistance to inflow of water into the water pipe and a small resistance to discharging water from the water pipe is interposed.

Further, the inflow resistance of the fluid passage and the capacity of the water retaining pipe are determined according to the magnitude of the negative pressure generated in the water pipe and the duration of the negative pressure due to the sudden stop of the pump for supplying water into the water pipe. May be set so that air does not flow into the water supply pipe.

Further, the fluid passage is constituted by a valve body which is closed by inflow of water into the water supply pipe and opened by drainage, and a small hole which is formed in the valve body and regulates the inflow resistance. You can also

Then, the fluid passage is closed by the inflow of water into the water supply pipe and opened by the discharge, a communication pipe provided in parallel with the valve body, and a communication pipe interposed in the communication pipe. And a throttle valve that regulates the inflow resistance.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to FIG. FIG. 1 is a vertical sectional view of an embodiment of the air valve device of the present invention. 1, the same members as those in FIG. 3 are designated by the same reference numerals.

In FIG. 1, an air valve 20 is provided on a convex portion 14a of the water supply pipe 14 and the like via a water retention pipe 18. The fluid passage 30 is interposed in the water retaining pipe 18. The fluid passage 30 allows water to flow into the water pipe 14 (direction of arrow A).
The valve body 32 is closed by and is opened by discharging (in the direction of arrow B). Moreover, the valve body 32 is provided with a small hole 34.
The small hole 34 is provided in the water pipe 1 when the valve body 32 is closed.
It regulates the inflow resistance of water to No. 4. Further, the small hole 34 of the valve body 32 is also for preventing the water supply pipe 14 and the water retention pipe 18 from being completely shut off by the blockage of the valve body 32 so that they are always in a communicating state. Therefore,
The high pulsating pressure during normal operation is due to the valve body 32 and the air valve 20.
The small holes 34 act so as to prevent the valve body 32 and the spherical float 42 from being locked together by being enclosed in the water retaining pipe 18 between the spherical floats 42, which will be described later. Further, 36 is a swing shaft for freely swinging the valve body 32 to be closed and opened, and 38 is a valve seat with which the valve body 32 abuts in the closed state.

Although the air valve 20 is well known, its structure will be briefly described. Air valve 20 is cup-shaped 2
A plurality of wall bodies are stacked with a gap therebetween, and the inner cup-shaped wall body is used as a valve chamber 40 to accommodate a spherical float 42 as a valve. This spherical float 42 has a specific gravity that floats on water, and the valve chamber 40
It can move up and down freely. The upper end of the double cup-shaped wall is closed by a plate provided with an opening / closing port 44 that is closed by the rising of the spherical float 42. Further, the spherical float 42 is opened in the descending position on the inner cup-shaped wall through the through hole 4
6, 46 are bored so that the valve chamber 40 and the gap between the double wall bodies communicate with each other. The gap between the double wall bodies communicates with the water retention pipe 18. A dust cover 50 is appropriately provided above the air valve 20.

In such a configuration, in the operating state of the pump 16, the water supply pipe 14 and the water retention pipe 18 are filled with water, the spherical float 42 is in the raised position, and the air valve 20 is in the closed state. Here, when the pump 16 suddenly stops operating, a negative pressure is generated in the water supply pipe 14, and the water in the water retention pipe 18 flows into the water supply pipe 14 through the small hole 34 of the valve body 32 (direction of arrow A). ) Do. Here, the valve body 32 itself is closed. The capacity of the water retention pipe 18 above the fluid passage 30 is
The water storage capacity is set so that air does not flow into the water pipe 14. In these pumping pump systems, the magnitude of the negative pressure and the duration of the negative pressure that would be generated by the water in the water pipe 14 moving due to inertia when the pump 16 is stopped are analyzed in advance, and the data is obtained. It may be set appropriately based on the above.

When the movement of water due to inertia is stopped and the reverse flow is started, the valve body 32 is opened and the water flows into the water retention pipe 18 (in the direction of arrow B) so that the air in the water retention pipe 18 becomes water. Is replaced with. When the water retaining pipe 18 is filled with water, the air valve 20 is closed.

By the way, in the air valve device of the present invention, the inflow resistance due to the small holes 34 suppresses the movement of the water which tends to move in the water pipe 14 by inertia when the pump 16 suddenly stops. As described above, the amount of movement of water is smaller than that of the conventional one in which air can freely flow into the water supply pipe 14 from the air valve 20 as shown in FIG. Therefore, the flow velocity of water when water flows backward and the air valve 20 is closed becomes significantly smaller than that shown in FIG. Therefore, the pressure that rises due to the closing of the air valve 20 can be suppressed to a significantly small value.

Further, by appropriately setting the water storage capacity of the water retention pipe 18, air does not flow into the water supply pipe 14 and no air remains in the water supply pipe 14, so the pump 16
The air hammer phenomenon does not occur due to the restart of the. Moreover, the small hole 34 allows the water retaining pipe 18 to pass through the water pipe 14.
Since the inflow to the water is suppressed by a large inflow resistance, the inflow amount is small and the water storage capacity of the water retaining pipe 18 is accordingly small. Therefore, the water retention pipe 18 can be downsized. further,
Since air does not flow into the water pipe 14, the magnitude of the negative pressure when the negative pressure is generated is equal to or higher than the vapor pressure of water (for example, -0.7 kg /
By taking appropriate measures such as a flywheel so that the water column is maintained at (cm ² or more), water column separation will not occur.
Therefore, the flywheel or the like can be downsized and the installation space can be reduced as compared with the conventional one in which the flywheel or the like is provided so as to keep the inside of the water supply pipe 14 at a positive pressure.

FIG. 2 is a vertical sectional view of another embodiment of the air valve device of the present invention. In FIG. 2, the same members as those in FIG. 1 are designated by the same reference numerals, and duplicate description will be omitted.

In the other embodiment shown in FIG. 2, the structure of the fluid passage 30 of the embodiment shown in FIG. 1 is partially different. The difference will be described below. Fluid passage 60 shown in FIG.
Has a valve body 32 which is closed by inflow of water to the water supply pipe 14 and opened by discharge of water, but the valve body 32 is not provided with a small hole 34 as in the case of FIG. A communication pipe 62 that opens upstream and downstream of the valve body 32 is provided in parallel with the valve body 32, and a throttle valve 64 is interposed in the communication pipe 62.

In the configuration of FIG. 2, the throttle valve 64 is set to have an appropriate resistance. Then, the water pipe 1
With respect to the inflow of water (in the direction of arrow A), the valve body 32 is closed and appropriate inflow resistance is given through the throttle valve 64. Then, with respect to the inflow of water from the water supply pipe 14 to the water retention pipe 18 (direction of arrow B), the valve body 32 is opened and a small discharge resistance is given. Therefore, the other embodiment shown in FIG. 2 also has the same operation as the one embodiment shown in FIG.

In the above embodiment, the fluid passages 30 and 6 are
Although 0 is interposed in the water retention pipe 18, it is not limited to this, and it goes without saying that it may be interposed between the water supply pipe 14 and the water retention pipe 18. Further, the water retention pipe 18 is not limited to a cylindrical shape, and a chamber having an appropriate water storage capacity may be interposed between the water retention pipe 18 and the air valve 20. Further, the fluid passages 30, 60
Is not limited to the structure of the above-described embodiment, and may have a large inflow resistance with respect to the inflow of water from the water retention pipe 18 to the water supply pipe 14, and vice versa having a small discharge resistance, for example, the valve element 32. Alternatively, a check valve may be provided so that the action of the throttle valve 64 can be achieved by the fluid resistance of the thin communication pipe 62.

[0024]

As described above, since the air valve device of the present invention is constructed, the following special effects are obtained.

In the air valve device according to the first aspect of the present invention, since the resistance of water flowing from the water retaining pipe to the water supply pipe is large, it is possible to suppress the movement of the water in the water pipe due to the inertia due to the sudden stop of the pump. As a result, the moving amount of water can be reduced as compared with the conventional air valve device. Therefore, it is possible to reduce the flow velocity of water immediately before the air valve is closed by stopping the movement of water due to inertia and further backflow, and thus reducing the flow velocity change of the water when the air valve is closed. The pressure rise can be suppressed.

Further, in the air valve device according to the second aspect, when the pump is stopped, the water flows into the water supply pipe due to the negative pressure generated in the water supply pipe due to the movement due to the inertia of the water.
Since the storage capacity of the water retention pipe is set to a size such that air does not flow into the water supply pipe, air does not flow into the water supply pipe, and the air pool and the air hammer phenomenon caused by the inflow air do not occur. Therefore, when the pump is restarted, it is not necessary to perform a careful bleeding operation so as not to cause an air hammer phenomenon, and the operation is so easy, and the safety is improved because the air hammer phenomenon does not occur. And the inflow of water from the water retention pipe to the water pipe,
Since it is suppressed by the large inflow resistance of the small holes, the inflow amount is small, and the water storage capacity of the water retention pipe is small accordingly, and the water retention pipe can be downsized. Furthermore, since air does not flow into the water pipe, it is sufficient to keep the water pipe pressure higher than the vapor pressure of water.For this reason, a flywheel or the like must be kept positive in the water pipe like the conventional one. It can be made smaller than the one that must be used. Therefore, the air valve device of the present invention can reduce the installation space.

Further, in the air valve device according to the third aspect, the fluid passage having a large inflow resistance and a small discharge resistance can be easily constructed.

Further, in the air valve device according to the fourth aspect, the fluid passage is composed of a general valve body, a throttle valve, and a general-purpose component of a communicating pipe, which is suitable for a small amount of production.

[Brief description of drawings]

FIG. 1 is a vertical sectional view of an embodiment of an air valve device of the present invention.

FIG. 2 is a vertical cross-sectional view of another embodiment of the air valve device of the present invention.

FIG. 3 is a diagram showing an example of a general pumping pump system.

[Explanation of symbols]

 14 water supply pipe 16 pump 18 water retention pipe 20 air valve 30,60 fluid passage 32 valve body 34 small hole 62 communication pipe 64 throttle valve

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display area F17D 1/20 F17D 1/20

Claims (4)

[Claims] 1. A water pipe forming a long pipe water channel is provided with an air valve via a water retention pipe, and the water flow resistance to the water pipe is large between the water pipe and the water retention pipe or in the water retention pipe. An air valve device comprising a fluid passage having a small resistance to discharge water from a water supply pipe. 2. The air valve device according to claim 1, wherein the fluid is responsive to the magnitude of the negative pressure generated in the water pipe and the duration of the negative pressure due to a sudden stop of a pump for feeding water into the water pipe. An air valve device characterized in that an inflow resistance of a passage and a capacity of the water retention pipe are set so that air does not flow into the water transmission pipe. 3. The air valve device according to claim 1, wherein the fluid passage is closed by inflow of water into the water supply pipe and opened by discharge, and the valve body is provided with a hole. An air valve device comprising a small hole for regulating the inflow resistance. 4. The air valve device according to claim 1, wherein the fluid passage is provided in parallel with the valve body, which is closed by inflow of water into the water supply pipe and opened by discharge. An air valve device comprising: a communication pipe; and a throttle valve interposed in the communication pipe to regulate the inflow resistance.